Neuromuscular Advances 2016-10-11 - distribution a · mortality rates of myasthenia gravis and...
Transcript of Neuromuscular Advances 2016-10-11 - distribution a · mortality rates of myasthenia gravis and...
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Updates on Neuromuscular Disorders
2016
J. Douglas Miles, M.D., Ph.D.University of Hawai‘i
John A. Burns School of MedicineOctober 22, 2016
Who is This Guy?Why is he Keeping me Awake?
• Neurologist
• Fellowship in neuromuscular medicine at Case Western Reserve
• Certified in neuromuscular medicine by the ABPN
• Certified in electrodiagnostic medicine by the ABEM
• Member of the Medical/Scientific advisory board for the Myasthenia Gravis Foundation of America
Disclosures
• Physician at MDA clinic
• No other financial disclosures
• Some off‐label uses will be discussed
• Some slides in this presentation were provided by the companies who developed the drugs being discussed
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Learning Objectives
At the conclusion of this activity, participants will be able to…
1. Explain the pathophysiology of neuromuscular diseases for which new possible treatments are being investigated
2. Describe some of the recent and ongoing clinical trials investigating possible treatments for neuromuscular diseases.
3. Recognize how exon‐skipping therapies may benefit patients with Duchenne muscular dystrophy.
What We’re Going to Cover Today
• What do you mean, “neuromuscular disorders?”
• Myasthenia Gravis and Thymectomy
• Duchenne Muscular Dystrophy and Eteplirsen
• SMA and nusinersen
• CMT 1‐A and PXT3003
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Axon
Terminal Bouton
Vesicles filled with ACh
Muscle Fiber
Nervous System
Brain
Spinal cord
Anterior horn cells
Roots
Plexuses
Nerves
NMJ
Muscle
Medical Speak
Brain ------------------------- Encephalopathy
Spinal cord ----------------- Myelopathy
Anterior horn cells --------- Motor neuron disease
Roots ----------------------- Radiculopathy
Plexuses --------------------- Plexopathy
Nerves ---------------------- Neuropathy
NMJ ------------------------- NMJ disorder
Muscle --------------------- Myopathy
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Central Nervous System
Brain ------------- CNS
Spinal cord ----- CNS
Anterior horn cells
Roots
Plexuses
Nerves
NMJ
Muscle
Peripheral Nervous System
Brain ------------- CNS
Spinal cord ----- CNS
Anterior horn cells
Roots
Plexuses
Nerves
NMJ
Muscle
Neuromuscular Disorders
Anterior horn cells --------- Motor neuron disease
Roots ----------------------- Radiculopathy
Plexuses --------------------- Plexopathy
Nerves ---------------------- Neuropathy
NMJ ------------------------- NMJ disorder
Muscle --------------------- Myopathy
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Today’s Topics
Anterior horn cells ------- Spinal Muscular Atrophy
Nerves -------------------- CMT 1-A
NMJ ----------------------- Myasthenia Gravis
Muscle ------------------- DMD
Myasthenia Gravis and Thymectomy
Myasthenia Gravis and Thymectomy
What is Myasthenia Gravis?
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Neuromuscular Disorders
Anterior horn cells --------- Motor neuron disease
Roots ----------------------- Radiculopathy
Plexuses --------------------- Plexopathy
Nerves ---------------------- Neuropathy
NMJ ------------------------- NMJ disorder
Muscle --------------------- Myopathy
A Brief History of Myasthenia
• Term coined in 1895 by Friedrich Jolly
• Earlier cases were described
• Thomas Willis in De Anima Brutorum 1672
Source: • Henry J. Kaminski (Editor). Myasthenia Gravis and Related Disorders (Current Clinical
Neurology). Humana Press (ISBN:1588298523)• Kaminski, H.J., “Myasthenia Gravis,” in Katirji, B, Kaminski, H.J., and Ruff, R. (Editors)
Neuromuscular Disorders in Clinical Practice, 2nd ed. Springer. 2013.
Typical History
• Weakness, ptosis, diplopia, blurred vision, dysphagia, or dyspnea• Fluctuating course• Better in the morning, worse at night• Better in cold weather, worse with heat• Worse after exercise, or other fatigue• Gradual or rapid onset• Perhaps precipitated by new medication• No sensory symptoms• Painless
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Physical Exam Findings
• Weakness, ptosis, dysconjugate gaze
• Strength or ptosis worsens with continued effort
• Ptosis may improve with ice pack
• Otherwise normal neurological exam
muscle fiber
axon
vesicles of acetylcholine
synaptic cleft
invaginations
Image Source: Pakistan Myasthenic Welfare Organizationhttp://www.pmwo.org.pk/mg.html
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Overall Incidence
• 2.1 to 5.0 per million people per year
• This has not changed much over the years
Sources:• Alshekhlee, A., Miles, J.D., Katirji, B., Preston, D., & Kaminski, H. (2009, May). Incidence and
mortality rates of myasthenia gravis and myasthenic crisis in US hospitals. Neurology 72:1548-1554. PMID: 19414721.
• Christensen PB, Jensen TS, Tsiropoulos I, et al. Incidence and prevalence of myasthenia gravis in western Denmark: 1975 to 1989. Neurology 1993;43:1779–1783.
• Phillips LH, Torner JC. Epidemiologic evidence for a changing natural history of myasthenia gravis. Neurology 1996;47:1233–1238.
• Oosterhuis HJ. The natural course of myasthenia gravis: a long term follow up study. J NeurolNeurosurg Psychiatry 1989;52:1121–1127.
Prevalence
• Prevalence rate has increased since the 1950s
• declining mortality rate
• Estimated to be about 20 per 100,000
Sources:• Phillips, L.H. (2003). "The epidemiology of myasthenia gravis." Ann N Thymectomy Acad Sci, 998
407-12. (PMID:14592908)• Murthy JMK, Meena AK, Chowdary GVS, Naryanan JT. Myasthenic crisis: clinical features,
complications and mortality. Neurology India 2005;53:37–40.• Thomas CE, Mayer SA, Gungor Thymectomy, et al. Myasthenic crisis: clinical features, mortality,
complications, and risk factors for prolonged intubation. Neurology 1997; 48:1253–1260.• Ferguson IT, Murphy RP, Lascelles RG. Ventilatory failure in myasthenia gravis. J Neurol
Neurosurg Psychiatry 1982;45:217–222.• Varelas PN, Chua HC, Natterman J, et al. Ventilatory care in myasthenia gravis crisis: Assessing
the baseline adverse event rate. Crit Care Med 2002;30:2663–2668.• Phillips LH. The epidemiology of myasthenia gravis. Ann NY Acad Sci 2003;998:407–412.
MG in Hawai‘i
• Expected Incidence:
5 new cases per year
• Expected Prevalence:
284 people
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Hospital Admissions
Source: Alshekhlee, A., Miles, J.D., Katirji, B., Preston, D., & Kaminski, H. (2009, May). Incidence and mortality rates of myasthenia gravis and myasthenic crisis in US hospitals. Neurology 72:1548-1554. PMID: 19414721.
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1-10 11-20 21-30 31-40 41-50 51-60 61-70 71-80
Age (years)
male
female
Source: Li, A, Takhar, Tahara, K, Lee, R, Beckwith, N, Ghaffari-Rafi, A, J, Sabugo, J, & Miles, JD. Ethnicity and Age of Patients Hospitalized with Myasthenia Gravis: Unique Demographics in Hawai‘i. Poster presentation at the American Academy of Neurology 68th Annual Meeting, April 2016. Vancouver.
MG in Hawai‘i
Clinical Course
• Not progressive
• Fluctuating symptoms
• Risk of worsening
• Risk of MG Crisis
• Very variable from patient to patient
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Ocular Myasthenia Gravis
• 35% of MG patients present with purely ocular symptoms
• 50‐80% will progress to generalized disease
• Believed to be most likely in first 2 years
Cookie Monster © Sesame WorkshopSources:• Nair AG, Patil-Chhablani P, Venkatramani DV, Gandhi RA. Ocular myasthenia gravis:
A review. Indian Journal of Ophthalmology. 2014;62(10):985-991. • Kaminski, H.J., “Myasthenia Gravis,” in Katirji, B, Kaminski, H.J., and Ruff, R. (Editors)
Neuromuscular Disorders in Clinical Practice, 2nd ed. Springer. 2013.
Myasthenia Gravis Crisis
• MG exacerbation that leads to respiratory failure
• Weakness of respiratory muscles
• Weakness of bulbar muscles
• Most severe complication of MG
• Requires critical care
Source:• Alshekhlee, A., Miles, J.D., Katirji, B., Preston, D., & Kaminski, H. (2009, May).
Incidence and mortality rates of myasthenia gravis and myasthenic crisis in US hospitals. Neurology 72:1548-1554. PMID: 19414721.
Mortality
• Appx. 30% in the mid‐1950s
• Closer to 3% in the late 1990s
Sources:• Christensen PB, Jensen TS, Tsiropoulos I, et al. Mortality and survival in myasthenia
gravis: a Danish population based study. J Neurol Neurosurg Psychiatry 1998;64: 78–83.
• Rowland LP, Hoefer PF, Aranow H, Merritt HH. Fatalities in myasthenia gravis: a review of 39 cases with 26 autopsies. Neurology 1958;6:310–326.
• Hill M, Ben-Shlomo Thymectomy. Neurological care and risk of hospital mortality for patients with myasthenia gravis in England. J Neurol Neurosurg Psychiatry 2008;79:421–425.
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3 Main Treatments
• Cholinesterase inhibitors (pyridostigmine)
• Corticosteroids
• “Steroid‐sparing” agents
Pyridostigmine Bromide
• aka Mestinon
• 60mg tabs
• 30 – 60 mg to start
• Can go higher
• > 180mg rarely effective
• Q 3 – 6 hours
• Sustained‐release available
Source: Kaminski, H.J., “Myasthenia Gravis,” in Katirji, B, Kaminski, H.J., and Ruff, R. (Editors) Neuromuscular Disorders in Clinical Practice, 2nd ed. Springer. 2013.
Corticosteroids
• No agreement as to optimal dose
• High doses often recommended (80‐100mg/day)
• Alternate‐day treatment also suggested
• Slow taper down
• Up to 20% of patients need prednisone for life
Source: Kaminski, H.J., “Myasthenia Gravis,” in Katirji, B, Kaminski, H.J., and Ruff, R. (Editors) Neuromuscular Disorders in Clinical Practice, 2nd ed. Springer. 2013.
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Steroid‐Sparing Agents
• Allow patients to be on lower doses of prednisone, or even to get off prednisone
• Take months for effect to be seen
• Azathioprine
• Mycophenolate Mofetil
• Cyclosporine
AAN Guidelines
• “…the benefit of thymectomy in nonthymomatous autoimmune MG has not been established conclusively.”
• “For patients with nonthymomatous autoimmune MG, thymectomy is recommended as an option to increase the probability of remission or improvement (Class II).”
Source: Gronseth, G.S., and Barohn, R.J. (2000). "Practice parameter: thymectomy for autoimmune myasthenia gravis (an evidence-based review): report of the Quality Standards Subcommittee of the American Academy of Neurology." Neurology, 55(1) 7-15. (PMID:10891896)
Myasthenia Gravis and Thymectomy
What is Thymectomy?
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Why would anyone think of this?
• 1939, Blalock et al. removed a cystic thymictumor from a 21 year‐old woman
• Her MG remitted• They tried it in other MG patients with no thymoma
• found hyperplasia in the thymus • reported improvement in at least half of their patients.
Source: Gronseth, G.S., and Barohn, R.J. (2000). "Practice parameter: thymectomy for autoimmune myasthenia gravis (an evidence-based review): report of the Quality Standards Subcommittee of the American Academy of Neurology." Neurology, 55(1) 7-15. (PMID:10891896)
Thymus
• The pathophysiology involves T‐cell mediated immunity
• Thymic pathology in 80‐90% of MG patients
• About 15% of MG patients have thymoma
Source:Marx, A., Müller-Hermelink, H.K., and Ströbel, P. (2003). "The role of thymomas in the development of myasthenia gravis." Ann N Thymectomy Acad Sci, 998 223-36. (PMID:14592880)
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Thymectomy
• Goal is stable remission
• Various success rates cited: 15%, 64%, 90%, depending on source
• Expert consensus is that thymectomy can be useful for some patients
Source: Kaminski, H.J., “Myasthenia Gravis,” in Katirji, B, Kaminski, H.J., and Ruff, R. (Editors) Neuromuscular Disorders in Clinical Practice, 2nd ed. Springer. 2013.
Thymectomy
• Believed to be best performed within the first few years of diagnosis
• Usually recommended for patients < age 60
Source: Kaminski, H.J., “Myasthenia Gravis,” in Katirji, B, Kaminski, H.J., and Ruff, R. (Editors) Neuromuscular Disorders in Clinical Practice, 2nd ed. Springer. 2013.
MGTX Trial
• Thymectomy Trial in Non‐ThymomatousMyasthenia Gravis Patients Receiving Prednisone Therapy
• Estimated enrollment: 126
• Study Start Date: June 2006
• Study Completion Date: July 2016
Source: ClinicalTrials.gov NCT00294658
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Future Treatments?
• Studies ongoing with monoclonal antibodies
– Rituximab
– Eculizumab
Duchenne Muscular Dystrophy and Eteplirsen
Duchenne Muscular Dystrophy and Eteplirsen
What is Duchenne Muscular Dystrophy?
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Neuromuscular Disorders
Anterior horn cells --------- Motor neuron disease
Roots ----------------------- Radiculopathy
Plexuses --------------------- Plexopathy
Nerves ---------------------- Neuropathy
NMJ ------------------------- NMJ disorder
Muscle --------------------- Myopathy
Dystrophin
First gene identified by positional cloning
Large gene (the average gene consists of 3000 bases; the dystrophin gene comprises 2.4 million) Short arm of Myasthenia Gravis chromosome
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Dystrophin
Actin
Dystrophin IHC - Normal
Duchenne muscular dystrophy
Early childhood weaknessGower signCalf hypertrophyWheelchair dependence by age 12Death from cardiomyopathy with conduction defects, respiratory weakness, & pneumonia
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Duchenne muscular dystrophy
Dystrophin
Actin
Duchenne muscular dystrophy
Actin
Dystrophin: Duchenne
“Revertant fibers” result from reading frame restoring mutations
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Dystrophinopathy: Diagnosis
Deletions or duplications in DNA isolated from peripheral blood ~70% of Duchenne ~85% of Becker
Muscle biopsy Immunostaining for dystrophin Immunblot analysis Evaluation of related proteins
Duchenne Muscular Dystrophy and Eteplirsen
What is Eteplirsen?
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Spinal Muscular Atrophy and Nusinersen
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Spinal Muscular Atrophy and Nusinersen
What is Spinal Muscular Atrophy?
Neuromuscular Disorders
Anterior horn cells --------- Motor neuron disease
Roots ----------------------- Radiculopathy
Plexuses --------------------- Plexopathy
Nerves ---------------------- Neuropathy
NMJ ------------------------- NMJ disorder
Muscle --------------------- Myopathy
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Spinal Muscular Atrophy‐ Description ‐
• Loss of lower motor neurons
• Subtypes named for age of onset
• Progressive weakness
SMA Type 1
• Most severe
• Most common (60% of SMA)
• Very early onset. “Floppy baby syndrome”
• Weakness interferes with breathing, coughing, and swallowing.
• High mortality at a young age
SMA Type II
• Typical onset between 6 and 24 months
• Weakness is less severe
• Affected individuals unable to walk
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SMA Type III
• Typical onset after 18 months
• Affected individuals may initially be able to walk, but as weakness worsens, they may become wheelchair‐bound
SMA Type IV
• Onset in adolescence or adulthood
• Less severe, may still be progressive
• Rare
Spinal Muscular Atrophy‐ genetics ‐
• Caused by mutations in survival motor neuron 1 gene (SMN1)
• Results in deficiency of SMN protein
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Spinal Muscular Atrophy‐ genetics ‐
• There is a second gene, called SMN2, that produces SMN protein in insufficient amounts
• The number of SMN2 gene copies correlates with clinical phenotype
Spinal Muscular Atrophy and Nusinersen
What is Nusinersen?
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Nusinersen
• Antisense oligonucleotide
• Modifies splicing of the SMN2 precursor mRNA
• Increases the levels of full length SMN2
• Promotes increased production of functional SMN protein
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CMT 1‐A and PXT3003
CMT 1‐A and PTX3003
What is CMT 1‐A?
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Neuromuscular Disorders
Anterior horn cells --------- Motor neuron disease
Roots ----------------------- Radiculopathy
Plexuses --------------------- Plexopathy
Nerves ---------------------- Neuropathy
NMJ ------------------------- NMJ disorder
Muscle --------------------- Myopathy
CMT 1‐A‐ Description ‐
• CMT refers to inherited sensorimotor peripheral polyneuropathies
• 90 different genes
• CMT 1 is demyelinating
Sources:• http://www.cmtausa.org/understanding-cmt/types-and-causes/
CMT 1‐A‐ Pathophysiology ‐
• Genetic disease
• Autosomal dominant
• Duplication of peripheral myelin protein‐22 (PMP‐22).
• Overexpression of PMP‐22 causes abnormal myelin structure and function
Sources:• http://www.pharnext.com/en/pipeline-2/cmt-program/• http://www.cmtausa.org/understanding-cmt/types-and-causes/
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CMT 1‐A‐ Impressive‐Sounding Numbers ‐
• CMT Affects appx. 1 in 2,500 people in the United States
• CMT 1 accounts for about 55% of all cases of CMT
• CMT 1‐A accounts for about 66% CMT 1
Sources:• http://www.ninds.nih.gov/disorders/charcot_marie_tooth/detail_charcot_marie_tooth.htm• http://www.cmtausa.org/understanding-cmt/types-and-causes/
CMT in Hawai‘i
• Expected Prevalence:
– 568 people with CMT
– 206 people with CMT 1A
CMT 1‐A‐ So What's the Deal? ‐
• No effective treatment for any form of CMT
• Many agents have been evaluated
• Supportive care, orthotics, PT and OT are mainstay of treatment
Source:• Ekins S, et al. A brief review of recent Charcot‐Marie‐Tooth research and priorities. F1000Res.
2015 Feb 26;4:53.
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CMT 1‐A and PTX3003
What is PTX3003?
PTX3003‐ Description ‐
• A “pleodrug”
• “a fixed dose combination of (RS)‐baclofen, naltrexone hydrochloride and D‐sorbitol selected via a Systems Biology approach and developed by Pharnext, with the aim to lower toxic PMP22 gene over‐expression in CMT1A.”
Sources: • https://www.pharnext.com/en/• https://clinicaltrials.gov/ct2/show/NCT02579759
What is PTX3003?
• From Phase 2 trial, High Dose:
– 6 mg baclofen
– 0.7 mg naltrexone
– 210 mg sorbitol
• Uncertain what doses being tested in Phase 3 trial
Sources: • Attarian S, et al. An exploratory randomised double-blind and placebo-controlled phase 2 study of a combination of
baclofen, naltrexone and sorbitol (PXT3003) in patients with Charcot-Marie-Tooth disease type 1A. Orphanet J Rare Dis. 2014 Dec 18;9:199.
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Other treatments tried for CMT 1‐A
• Vitamin C
• Vitamin A
• Vitamin E
Sources: • Kaya, F., Belin, S., Micallef, J., Blin, O. and Fontés, M. (2008), Analysis of the benefits of vitamin cocktails in treating
Charcot–Marie–Tooth disease type 1A. Muscle Nerve, 38: 1052–1054..
PTX3003
• “Pharmacology‐network based drug repurposing”
Source: Chumakov, I. et al. 2014. Polytherapy with a combination of three repurposed drugs (PXT3003) down-regulates Pmp22 over-expression and improves myelination, axonal and functional parameters in models of CMT1A neuropathy. Orphanet Journal of Rare Diseases 9:201
PTX3003‐ How Does it Work? ‐
• “The proprietary R&D platform of Pharnext is based on network pharmacology. It allows the development of synergistic combinations of repositioned drugs – pleodrugs – which benefit from an outstanding safety profile and IP with strong enforceability.”
Source: https://www.pharnext.com/en/
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Source: Chumakov, I. et al. 2014. Polytherapy with a combination of three repurposed drugs (PXT3003) down-regulates Pmp22 over-expression and improves myelination, axonal and functional parameters in models of CMT1A neuropathy. Orphanet Journal of Rare Diseases 9:201
Source: Chumakov, I. et al. 2014. Polytherapy with a combination of three repurposed drugs (PXT3003) down-regulates Pmp22 over-expression and improves myelination, axonal and functional parameters in models of CMT1A neuropathy. Orphanet Journal of Rare Diseases 9:201
PTX3003
• “Eventually, three drugs – (RS)‐baclofen, naltrexone and D‐sorbitol – were chosen for testing in the relevant cellular and animal models of CMT1A.”
Source: Chumakov, I. et al. 2014. Polytherapy with a combination of three repurposed drugs (PXT3003) down-regulates Pmp22 over-expression and improves myelination, axonal and functional parameters in models of CMT1A neuropathy. Orphanet Journal of Rare Diseases 9:201
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Source: http://www.pharnext.com/en/pipeline-2/cmt-program
PTX3003‐What’s the Evidence? ‐
• Preclinical studies
• Phase II study
• Recruitment now in process for Phase III
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PXT3003 Phase 2 Trial
• 80 adult patients with mild‐to‐moderate CMT1A received in double‐blind for 1 year Placebo or one of the 3 doses of PXT3003 tested
• Efficacy was assessed using the Charcot‐Marie‐Tooth Neuropathy Score (CMTNS) and the Overall Neuropathy Limitations Scale
• This trial confirmed the safety and tolerability of PXT3003.• The highest dose (HD) showed consistent evidence of improvement
beyond stabilization. • CMTNS showed significant improvement of 8% (0.4% ‐ 16.2%) in the
HD group versus the pool of all other groups• ONLS showed significant improvement of 12.1% (2% ‐ 23.2%) • HD group had significantly more patients who did not deteriorate
over one year
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PXT3003 Phase 3 Clinical Trial
• Estimated Enrollment: 300
• Study Start Date: December 2015
• Estimated Study Completion Date:December 2017
• Estimated Primary Completion Date:December 2017 (Final data collection date
for primary outcome measure)
Source: • https://clinicaltrials.gov/ct2/show/NCT02579759
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